Liquid fuel cell

ABSTRACT

A liquid fuel cell that includes a canister having a fuel reservoir and a burner assembly mounted upon the canister. The burner assembly contains a wick holding aperture that opens into the fuel reservoir and a wick that is made up of continuous fiber strands mounted in the tube. The wick is doubled over to create a crown that is vertically disposed above the top of the wick holding aperture and the two ends of the wick are arranged to pass down through the wick burner into the fuel reservoir. A number of fiber strands are severed in the crown region to create a small island of bristles which greatly enhances the wick&#39;s ability to be rapidly and efficiently ignited.

FIELD OF THE INVENTION

This invention relates to a liquid fuel cell and, in particular, to a liquid fuel cell that provides for more rapid and efficient lighting of the burner wick.

BACKGROUND OF THE INVENTION

Liquid fuel cells which contain a wick-type burner are widely used in restaurants, banquet halls, and the like to provide intimate table lighting for the customers or attendees and for heating or warming food. Many of these fuel cells presently utilize fuels that have a relatively low flash point and are thus highly volatile or become excessively volatile when heated, and can create a fire hazard. In addition, many of the low flash point fuels give off noxious vapors when burned which may be unpleasant when many fuel cells are burning at the same time within an enclosed hall or dining area.

As disclosed in U.S. Pat. No. 4,624,633 to Bandel, fuels have been developed for use in liquid fuel cells that overcome many of the disadvantages associated with the low flash point fuels. The newer fuels also provide extended burning times when compared to more volatile fuels. As a result, the newer fuels have found wide use in smaller size fuel cells that are typically utilized used for heating or warming food or providing intimate table lighting.

The time required to ignite the burner wick of a fuel cell containing a high flash point fuel, however, is considerably longer than that needed to light a fuel cell containing a fuel having a lower flash point. Although the difference in ignition time might be measured in seconds, the total time needed to light all the table lamps in a fair sized restaurant or hall can be considerable. The chance of producing a mislight is also greater due to the longer ignition time.

SUMMARY OF THE INVENTION

It is therefore a primary object of the invention to improve liquid fuel cells of the type used for table lighting.

It is a further object of the present invention to improve liquid fuel cells containing a fuel having a high flash point.

It is a still further object of the present invention to shorten the ignition time of a liquid fuel cell that contains a fuel having a high flash point.

Another object of the present invention is to improve the safety of fuel cells by allowing for the convenient use of higher flash point fuels.

These and other objects of the present invention are attained by a liquid fuel cell that includes a canister having a reservoir for holding a quantity of liquid fuel. A burner is mounted upon the canister which contains a vertically disposed wick holding aperture that opens into the fuel reservoir. A wick is mounted in the wick tube which is formed of continuous strands of a wicking material. The wick is doubled over to create a U-shaped crown in its mid-region with the ends of the wick passing down through the wick holding aperture into the reservoirs whereby fuel is drawn into the crown region by capillary action. A number of strands in the crown region are severed to create a small island made up of a series of short bristles at each discontinuation point which provide for a more rapid and efficient ignition of the burner wick.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of these and other objects of the present invention, reference will be made to the following detailed description of the invention which is to be read in association with the accompanying drawings, wherein:

FIG. 1 is an exploded view in perspective illustrating a table lamp embodying the teachings of the present invention;

FIG. 2 is an enlarged perspective view showing a liquid fuel cell suitable for use in the table lamp shown in FIG. 1; and

FIG. 3 is a further enlarged perspective view showing the wick in the burner section of the fuel cell being treated to produce bristle-like discontinuations in the wick fibers.

DETAILED DESCRIPTION OF THE INVENTION

Referring initially to FIG. 1, there is illustrated a lamp, generally referenced 10, for providing intimate lighting for a table or the like. The lamp assembly in this embodiment is a relatively small unit for producing intimate table lighting which now enjoys wide popularity in restaurants, banquet halls, and the like. The lamp is equipped with a disposable liquid fuel cell 12 that is removably fitted into a seat (not shown) located in the base 13 of the lamp. Although the present invention will be described with specific reference to a disposable fuel cell providing intimate table lighting, it should be obvious to one skilled in the art that the invention can be utilized in both disposable and reusable fuel cells that employ a wick type burner that can be used for other purposes such as chafing dish applications. The lamp itself may take any form that is aesthetically pleasing, as well as being able to function for its intended purpose. In this embodiment, the lamp includes a transparent, removable chimney or globe 15 having an open top which is securely fitted to the base.

Because most lamps used for intimate table lighting are relatively small in size, the fuel cell that can be accommodated within the base must be correspondingly small. As a consequence, the amount of fuel that can be stored within the reservoir of this cell is limited. As noted above, fuels having a high flash point above 200° F. have been developed for use in liquid fuel cells for safety reasons. In addition, fuels having a high flash point provide a longer burning time than those having a lower flash point, and are thus better suited for use in smaller fuel cells of the type utilized in lamps for intimate table lighting. The high flash point fuels, however, present certain challenges relative to the lower flash point fuels, one of which being an increased time to light the wick of the burner.

With further reference to FIGS. 2 and 3, the fuel cell 12 includes a canister 20 having a reservoir 21, which in the case of a tealight is capable of holding a limited amount of fuel. The canister is made of a transparent material so that the user will have a clear visual indication of the amount of fuel that remains in the cell. The canister is closed by a top mounted burner assembly that is generally referenced 25. The assembly includes a cap 27 that closes the top opening in the canister and a vertically disposed wick holding aperture 28 that is located in the center of the cap. The aperture may be a simple hole that is passed through the top cover of the cell or contained in a tube 29 mounted in the cover. The wick holding aperture opens into the fuel reservoir of the fuel cell.

A wick 30 is mounted in the wick holding aperture 28. The wick is fabricated from a number of continuous fiber strands that extend from one end 32 of the wick to the other end 33. In assembly, the wick is doubled over in its mid-region to create a crown 35 and the crown is drawn or otherwise passed upwardly through the wick holding aperture so that it extends some distance above the top of the burner. The two ends of the wick pass downwardly through the aperture into the fuel reservoir and typically are seated along the bottom wall of the reservoir so that both ends of the wick are well inundated within the fuel contained within the reservoir.

The wick may be fabricated of any one of many well-known wicking materials that are capable of drawing fuel from the reservoir into the wick crown region via capillary action. The crown of the wick is typically lighted by placing a flame in close proximity to the crown to heat the fuel to or beyond its flash point. In the case of a wick having unbroken strands, the time required to produce ignition is generally relatively long when compared to the ignition time associated with fuels having lower flash points, the ignition time generally being in the five to six second range in the case of fuels that have a flash point at or above 300° F.

Applicant, through experimentation, has found that the ignition time of a fuel cell of the type herein described can be considerably shortened by producing a discontinuation in a small group of fiber strands within the crown region. Suitable discontinuation of the wick strands can be produced by touching the crown surface with a wire 40 that is heated to a desired temperature by connecting the wire to a suitable source of electric power 42. The heated wire remains in contact with the wick until such time as a small island of short bristles 43 is created in the wire contact region whereupon the heated wire is removed from contact from the surface of the crown. Although a heated wire has been found to work well in practice, the fiber bristles may also be created using a sharp blade, a laser beam, a water knife, or any other suitable cutting instrument capable of severing a small number of strands in the crown region of the wick.

While the present invention has been described with specific reference to a fuel cell for use in a small lamp for providing intimate table lighting, it should be obvious to one skilled in the art that the invention has a broader application for use in any type of fuel cell that employs a fuel having a relatively high flash point. 

1. A liquid fuel cell that includes: a canister having a reservoir for holding a quantity of liquid fuel; a burner mounted upon said canister, said burner having a wick holding aperture that opens into said reservoir; a wick mounted in said wick holding aperture, said wick holding aperture being formed by a series of continuous strands that extend from one end of the wick to the other end of the wick; said wick being doubled over to form a U-shaped crown that extends above the top of said wick holding aperture and the ends of the wick passing downwardly through said wick holding aperture into the reservoir whereby liquid fuel is supplied to the crown via capillary action; and wherein a series of adjacent strands in the crown of the wick are severed to create a region of bristles to enhance the wick's ability to be rapidly and efficiently lighted.
 2. The fuel cell of claim 1, wherein said fuel has a relatively high flash point.
 3. The fuel cell of claim 2, wherein the flash point of said fuel is about 200° F. or greater.
 4. The fuel cell of claim 2, wherein the flash point of said fuel is above 300° F.
 5. A method of shortening the ignition time of a liquid fuel cell having a burner and a reservoir for holding a quantity of liquid fuel, said method including the steps of: providing a wick fabricated of continuous strands of wicking material that extend from one end of the wick to the other end of the wick; doubling over said wick to establish a U-shaped crown within the mid-region of the wick; mounting the wick within a wick holding aperture in said burner so that the crown of the wick extends above the top of the wick holding aperture and the ends of the wick pass downwardly through the wick holding aperture into said fuel reservoir; and modifying said wick by creating a plurality of bristles within a region of said crown by severing a number of strands within said region.
 6. The method of claim 5, wherein said bristles are created by touching a plurality of strands in the crown of the wick with a heated wire.
 7. The method of claim 5, wherein said bristles are created by slicing a plurality of adjacent strands within the crown with a cutting instrument.
 8. The method of claim 5 that includes the further step of filling the cell reservoir with a quantity of liquid fuel that has a relatively high flash point.
 9. The method of claim 8, wherein said reservoir is filled with a fuel having a flash point above 200° F.
 10. The method of claim 8, wherein said reservoir is filled with a fuel having a flash point above 300° F. 